Genomic Diversity of the Ostreid Herpesvirus Type 1 Across Time and Location and Among Host Species

The mechanisms underlying virus emergence are rarely well understood, making the appearance of outbreaks largely unpredictable. This is particularly true for pathogens with low per-site mutation rates, such as DNA viruses, that do not exhibit a large amount of evolutionary change among genetic sequences sampled at different time points. However, whole-genome sequencing can reveal the accumulation of novel genetic variation between samples, promising to render most, if not all, microbial pathogens measurably evolving and suitable for analytical techniques derived from population genetic theory. Here, we aim to assess the measurability of evolution on epidemiological time scales of the Ostreid herpesvirus 1 (OsHV-1), a double stranded DNA virus of which a new variant, OsHV-1 μVar, emerged in France in 2008, spreading across Europe and causing dramatic economic and ecological damage. We performed phylogenetic analyses of heterochronous (n = 21) OsHV-1 genomes sampled worldwide. Results show sufficient temporal signal in the viral sequences to proceed with phylogenetic molecular clock analyses and they indicate that the genetic diversity seen in these OsHV-1 isolates has arisen within the past three decades. OsHV-1 samples from France and New Zealand did not cluster together suggesting a spatial structuration of the viral populations. The genome-wide study of simple and complex polymorphisms shows that specific genomic regions are deleted in several isolates or accumulate a high number of substitutions. These contrasting and non-random patterns of polymorphism suggest that some genomic regions are affected by strong selective pressures. Interestingly, we also found variant genotypes within all infected individuals. Altogether, these results provide baseline evidence that whole genome sequencing could be used to study population dynamic processes of OsHV-1, and more broadly herpesviruses

Study of host/parasite interactions in the flat oyster Ostrea edulis and the parasite Bonamia ostreae

L’histoire de l’ostréiculture française met en évidence la fragilité de cette production face à la surexploitation des stocks et l’apparition de maladies. En particulier, la production d’huître plate, Ostrea edulis, a fortement diminué suite à l’apparition de deux maladies parasitaires dont la bonamiose. Les moyens de lutte contre la bonamiose sont relativement restreints. Ils sont essentiellement basés sur la surveillance de la santé des huîtres afin de limiter la dissémination et la propagation de la maladie. Cependant l’utilisation de modèles prédictifs de l’évolution de la maladie en zone infectée permettrait d’optimiser la gestion des stocks et minimiser l’impact des agents pathogènes. De plus, le développement d’animaux résistants à l’infection pourrait permettre de relancer cette production. Ces différentes approches nécessitent des outils diagnostiques adaptés, une bonne connaissance du cycle de vie de l’agent pathogène, et, plus particulièrement des interactions du parasite avec son hôte. Dans ce contexte, l’objectif principal du travail de thèse proposé est de comprendre les interactions entre l’huître plate Ostrea edulis et son parasite Bonamia ostreae, et, plus particulièrement les bases moléculaires de la résistance au parasite. Dans un premier temps, la réalisation d’une banque soustractive d’ADNc a permis d’identifier des ESTs différentiellement exprimées chez des hémocytes en réponse au parasite. L’expression de certains gènes dont une galectine a été mesurée en PCR en temps réel dans le contexte d’infections in vitro. En complément, la réponse cellulaire a été étudiée par cytométrie en flux et l’infection contrôlée en microscopie. Ces expériences ont montré une multiplication parasitaire dans les hémocytes au cours du temps associée à une diminution de la production d’EOR et d’estérases. Dans un second temps, il a été entrepris une étude comparative entre une population d’huîtres plates résistantes à la bonamiose et une population naturelle. Les résultats obtenus tendent à montrer qu’une modulation de l’apoptose et une diminution de la phagocytose seraient impliquées dans les mécanismes liés à la résistance à la bonamiose. Ce travail est le premier à étudier la réponse des hémocytes d’huîtres plates à une infection par le parasite Bonamia ostreae au niveau cellulaire et moléculaire.The history of the French oyster production highlights the fragility of this production against overexploitation and disease outbreaks. In particular, the production of flat oyster, Ostrea edulis, has decreased following the emergence of two parasitic diseases including bonamiosis. The means to fight against bonamiosis are relatively limited. They are mainly based on oyster health surveillance to limit the spread of the disease. However, the use of predictive models of disease progression in infected area would help to improve stock management and minimize the impact pathogens. Moreover the development of resistant animals could help to revive this production. These different approaches require appropriate diagnostic tools, a good knowledge of the life cycle of the pathogen, and the interactions between the parasite and its host. In this context, the main objective of the phD work is to understand the interactions between the flat oyster Ostrea edulis and the parasite Bonamia ostreae, and particularly the molecular basis of the resistance to the parasite. In a first step, a subtractive cDNA bank allowed the identification of ESTs differentially expressed in haemocytes in response to the parasite. Expression of some genes, among which a galectin, was measured by Real Time PCR in the context of in vitro infections. In addition, the cellular response was investigated by flow cytometry and the infection was checked by microscopy. These experiments showed a multiplication of the parasite inside haemocytes associated with a decreased of esterases and of the production of ROS. In a second step, a comparative approach was carried out between a population of oysters resistant to bonamiosis and a natural population. Results suggest that modulation of apopotosis and decrease of phagocytosis could be involved in mechanisms related to resistance to bonamiosis. This work is the first study on the response of haemocytes of flat oysters to an infection with the parasite Bonamia ostreae at the cellular and molecular levels

Etude des interactions hôte/parasite chez l’huître plate Ostrea edulis et son parasite Bonamia ostreae

The history of the French oyster production highlights the fragility of this production against overexploitation and disease outbreaks. In particular, the production of flat oyster, Ostrea edulis, has decreased following the emergence of two parasitic diseases including bonamiosis. The means to fight against bonamiosis are relatively limited. They are mainly based on oyster health surveillance to limit the spread of the disease. However, the use of predictive models of disease progression in infected area would help to improve stock management and minimize the impact pathogens. Moreover the development of resistant animals could help to revive this production. These different approaches require appropriate diagnostic tools, a good knowledge of the life cycle of the pathogen, and the interactions between the parasite and its host. In this context, the main objective of the phD work is to understand the interactions between the flat oyster Ostrea edulis and the parasite Bonamia ostreae, and particularly the molecular basis of the resistance to the parasite. In a first step, a subtractive cDNA bank allowed the identification of ESTs differentially expressed in haemocytes in response to the parasite. Expression of some genes, among which a galectin, was measured by Real Time PCR in the context of in vitro infections. In addition, the cellular response was investigated by flow cytometry and the infection was checked by microscopy. These experiments showed a multiplication of the parasite inside haemocytes associated with a decreased of esterases and of the production of ROS. In a second step, a comparative approach was carried out between a population of oysters resistant to bonamiosis and a natural population. Results suggest that modulation of apopotosis and decrease of phagocytosis could be involved in mechanisms related to resistance to bonamiosis. This work is the first study on the response of haemocytes of flat oysters to an infection with the parasite Bonamia ostreae at the cellular and molecular levels.L’histoire de l’ostréiculture française met en évidence la fragilité de cette production face à la surexploitation des stocks et l’apparition de maladies. En particulier, la production d’huître plate, Ostrea edulis, a fortement diminué suite à l’apparition de deux maladies parasitaires dont la bonamiose. Les moyens de lutte contre la bonamiose sont relativement restreints. Ils sont essentiellement basés sur la surveillance de la santé des huîtres afin de limiter la dissémination et la propagation de la maladie. Cependant l’utilisation de modèles prédictifs de l’évolution de la maladie en zone infectée permettrait d’optimiser la gestion des stocks et minimiser l’impact des agents pathogènes. De plus, le développement d’animaux résistants à l’infection pourrait permettre de relancer cette production. Ces différentes approches nécessitent des outils diagnostiques adaptés, une bonne connaissance du cycle de vie de l’agent pathogène, et, plus particulièrement des interactions du parasite avec son hôte. Dans ce contexte, l’objectif principal du travail de thèse proposé est de comprendre les interactions entre l’huître plate Ostrea edulis et son parasite Bonamia ostreae, et, plus particulièrement les bases moléculaires de la résistance au parasite. Dans un premier temps, la réalisation d’une banque soustractive d’ADNc a permis d’identifier des ESTs différentiellement exprimées chez des hémocytes en réponse au parasite. L’expression de certains gènes dont une galectine a été mesurée en PCR en temps réel dans le contexte d’infections in vitro. En complément, la réponse cellulaire a été étudiée par cytométrie en flux et l’infection contrôlée en microscopie. Ces expériences ont montré une multiplication parasitaire dans les hémocytes au cours du temps associée à une diminution de la production d’EOR et d’estérases. Dans un second temps, il a été entrepris une étude comparative entre une population d’huîtres plates résistantes à la bonamiose et une population naturelle. Les résultats obtenus tendent à montrer qu’une modulation de l’apoptose et une diminution de la phagocytose seraient impliquées dans les mécanismes liés à la résistance à la bonamiose. Ce travail est le premier à étudier la réponse des hémocytes d’huîtres plates à une infection par le parasite Bonamia ostreae au niveau cellulaire et moléculaire

Etude des interactions entre l'huître plate Ostrea edulis et le parasite Bonamia ostreae en cytométrie en flux et en hybridation soustractive suppressive (SSH)

The French ostreiculture history highlights the fragility of its production caused by stocks overexploitation and diseases. Particularly, the flat oyster production decreased a lot after the appearance of two parasitic diseases: marteilliose and bonamiose. The bonamiose is due to a parasite Bonamia ostreae. The study of interactions between the parasite and oysters hemocytes with flow cytometry allowed to identify modifications of hemocytes activities wh en active parasite is present. On the other hand, inactive parasite does not induce modification for the same hemocyte's activities. Finally, a new study approach, subtractive and suppressive hybridization, has been undertaken in order to identify genes expressed by hemocytes and parasites during in vitro infections.L'histoire de l'ostréiculture française met en évidence la fragilité de cette production face à la surexploitation des stocks et l'apparition de maladies. En particulier la production d' huître plate, Ostrea edulis, a fortement diminué suite à l'apparition de deux maladies parasitaires: la marteilliose et la bonamiose. Cette dernière est due au parasite Bonamia ostreae. L'étude des interactions entre le parasite et les hémocytes en cytométrie en flux a permis d'identifier des modifications des activités hémocytaires en présence de parasite actif. En revanche le parasite inactif n'induit pas de modification des activités mesurées. Une approche en hybridation soustractive sup~ressive a été initiée afin d' identifier des gènes exprimés par les hémocytes et le parasite au cours d'une infection in vitro

using Trypanosoma and Chlamydomonas models:

Getting to the heart of intraflagellar transpor

Getting to the heart of intraflagellar transport using Trypanosoma and Chlamydomonas models: the strength is in their differences.

International audienceCilia and flagella perform diverse roles in motility and sensory perception, and defects in their construction or their function are responsible for human genetic diseases termed ciliopathies. Cilia and flagella construction relies on intraflagellar transport (IFT), the bi-directional movement of 'trains' composed of protein complexes found between axoneme microtubules and the flagellum membrane. Although extensive information about IFT components and their mode of action were discovered in the green algae Chlamydomonas reinhardtii, other model organisms have revealed further insights about IFT. This is the case of Trypanosoma brucei, a flagellated protist responsible for sleeping sickness that is turning out to be an emerging model for studying IFT. In this article, we review different aspects of IFT, based on studies of Chlamydomonas and Trypanosoma. Data available from both models are examined to ask challenging questions about IFT such as the initiation of flagellum construction, the setting-up of IFT and the mode of formation of IFT trains, and their remodeling at the tip as well as their recycling at the base. Another outstanding question is the individual role played by the multiple IFT proteins. The use of different models, bringing their specific biological and experimental advantages, will be invaluable in order to obtain a global understanding of IFT

Propidium monoazide PCR, a method to determine OsHV-1 undamaged capsids and to estimate virus Lethal Dose 50

Ostreid herpes virus 1 (OsHV-1) has been classified within the Malacoherpesviridae family from the Herpesvirales order. OsHV-1 is the etiological agent of a contagious viral disease of Pacific oysters, C. gigas, affecting also other bivalve species. Mortality rates reported associated with the viral infection vary considerably between sites and countries and depend on the age of affected stocks. A variant called μVar has been reported since 2008 in Europe and other variants in Australia and in New Zealand last decade. These variants are considered as the main causative agents of mass mortality events affecting C. gigas. Presently there is no established cell line that allows for the detection of infectious OsHV-1. In this context, a technique of propidium monoazide (PMA) PCR was developed in order to quantify “undamaged” capsids. This methodology is of interest to explore the virus infectivity. Being able to quantify viral particles getting an undamaged capsid (not only an amount of viral DNA) in tissue homogenates prepared from infected oysters or in seawater samples can assist in the definition of a Lethal Dose (LD) 50 and gain information in the experiments conducted to reproduce the viral infection. The main objectives of the present study were (i) the development/optimization of a PMA PCR technique for OsHV-1 detection using the best quantity of PMA and verifying its effectiveness through heat treatment, (ii) the definition of the percentage of undamaged capsids in four different tissue homogenates prepared from infected Pacific oysters and (iii) the approach of a LD50 during experimental viral infection assays on the basis of a number of undamaged capsids. Although the developped PMA PCR technique was unable to determine OsHV-1 infectivity in viral supensions, it could greatly improve interpretation of virus positive results obtained by qPCR. This technique is not intended to replace the quantification of viral DNA by qPCR, but it does make it possible to give a form of biological meaning to the detection of this DNA

Viruses infecting marine molluscs

Although a wide range of viruses have been reported in marine molluscs, most of these reports rely on ultrastructural examination and few of these viruses have been fully characterized. The lack of marine mollusc cell lines restricts virus isolation capacities and subsequent characterization works. Our current knowledge is mostly restricted to viruses affecting farmed species such as oysters Crassostrea gigas, abalone Haliotis diversicolor supertexta or the scallop Chlamys farreri. Molecular approaches which are needed to identify virus affiliation have been carried out for a small number of viruses, most of them belonging to the Herpesviridae and birnaviridae families. These last years, the use of New Generation Sequencing approach has allowed increasing the number of sequenced viral genomes and has improved our capacity to investigate the diversity of viruses infecting marine molluscs. This new information has in turn allowed designing more efficient diagnostic tools. Moreover, the development of experimental infection protocols has answered some questions regarding the pathogenesis of these viruses and their interactions with their hosts. Control and management of viral diseases in molluscs mostly involve active surveillance, implementation of effective bio security measures and development of breeding programs. However factors triggering pathogen development and the life cycle and status of the viruses outside their mollusc hosts still need further investigations

Resistance to OsHV-1 Infection in Crassostrea gigas Larvae

The ostreid herpesvirus(OsHV-1) is one of the major diseases that affect the Pacific oyster Crassostrea gigas. Selective breeding programs were recently shown to improve resistance easily to OsHV-1 infections in spat, juvenile, and adult oysters. Nevertheless, this resistance has never been investigated in larvae, whereas this developmental stage has crucial importance for the production of commercial hatcheries, as well as explaining the abundance of spatfall. A first trial tested several viral suspensions at several concentrations using contaminated water with OsHV-1 in 4- and 10-day-old larvae that we reproduced from an unselected broodstock. In follow up on the results, one viral suspension at a final concentration of 10+6 OsHV-1 DNA copies per L was used to assess resistance to OsHV-1 infection in C.gigas larvae that we reproduced from selected and unselected broodstock. A second trial evaluated OsHV-1 resistance in larvae from both broodstocks intrials 2a, 2b, and 2c with 4,10, and 16-day-old larvae for 7 days, which corresponded to post D larvae, umbo larvae, and eyed larvae, respectively. The mortality of unchallenged larvae for both stocks were low (<15%) at day 7 intrials 2a and 2b, whereas it ranged from 48 to 56% in trial 2c. More interestingly, selected larvae had significantly lower mortality than unselected larvae when exposed to OsHV-1 in all of the trials. Thus, themortality was 11 and 49% for the selected larvae at day 7 post-exposure in trials 2a and 2c, respectively, in comparison with 84 and 97% for the unselected larvae. Although this difference in mortality was observed at day 5 in trial 2b, it was reduced at day 7, to 86 and 98% for the selected and unselected larvae, respectively. For the first time in the literature, the difference in mortality or the delayed on set of mortality between selected and unselected larvae have indicated a genetic resistance to OsHV-1 infection at the larval stage. Such finding should facilitate the selective breeding programs focusing on resistance to OsHV-1 infection by reducing the span of the genetic evaluation, and thus decreasing its cost

Susceptibility variation to the main pathogens of Crassostrea gigas at the larval, spat and juvenile stages using unselected and selected oysters to OsHV-1 and/or V. aestuarianus

French commercial hatcheries are massively producing Crassostrea gigas selected for their higher resistance to OsHV-1, and soon should also implement selection for increasing resistance to Vibrio aestuarianus. The first objective of this study was to optimize the breeding programs for dual resistance to OsHV-1 and V. aestuarianus to determine the earliest life stage for which oysters are able to develop disease resistance. Wild stocks and selected families were tested using experimental infections by both pathogens at the larval, spat and juvenile stages. Oyster families could be evaluated for OsHV-1 as soon as the larval stage by a bath method, but this only highlighted the most resistant families; those that showed the highest resistance to V. aestuarianus could be determined using the cohabitation method at the juvenile stage. The second objective of this study was to determine if selection to increase/decrease the resistance to OsHV-1 and V. aestuarianus could have an impact on other major pathogens currently detected in hatchery at the larval stage, and in nursery and field at the spat/juveniles stages (V. coralliilyticus, V. crassostreae, V. tasmaniensis, V.neptunius, V. europaeus, V. harveyi, V. chagasi). No relationship was found between mortality caused by V. aestuarianus/OsHV-1 and the mortality caused by the other virulent bacterial strains tested regardless the stages, except between OsHV-1 and V. tasmaniensis at the juvenile stage. Finally, miscellaneous findings were evidenced such as (1) bath for bacterial challenges was not adapted for spat, (2) the main pathogens at the larval stage were OsHV-1 and V. coralliilyticus using bath, while it was V. coralliilyticus, V. europaeus, and V. neptunius at the juvenile stage by injection, and (4) variation in mortality was observed among families/wild controls for all pathogens at larval and juvenile stages, except for V. harveyi for larvae